A fast and accurate method for computing the Sunyaev-Zeldovich signal of hot galaxy clusters

TL;DR

This paper introduces SZpack, a fast and precise computational tool for modeling the Sunyaev-Zeldovich effect in hot, moving galaxy clusters, accounting for relativistic and kinematic corrections with high accuracy.

Contribution

The paper presents a novel derivation of the Boltzmann collision term enabling rapid, accurate SZ signal calculations for hot clusters, improving upon previous methods.

Findings

SZpack achieves <0.001% accuracy at relevant frequencies.

The method efficiently handles high electron temperatures (~25 keV).

It effectively separates kinematic and scattering effects in SZ calculations.

Abstract

New generation ground and space-based CMB experiments have ushered in discoveries of massive galaxy clusters via the Sunyaev-Zeldovich (SZ) effect, providing a new window for studying cluster astrophysics and cosmology. Many of the newly discovered, SZ-selected clusters contain hot intracluster plasma (kTe > 10 keV) and exhibit disturbed morphology, indicative of frequent mergers with large peculiar velocity (v > 1000 km s^{-1}). It is well-known that for the interpretation of the SZ signal from hot, moving galaxy clusters, relativistic corrections must be taken into account, and in this work, we present a fast and accurate method for computing these effects. Our approach is based on an alternative derivation of the Boltzmann collision term which provides new physical insight into the sources of different kinematic corrections in the scattering problem. This allows us to obtain a clean separation of kinematic and scattering terms which differs from previous works. We briefly mention additional complications connected with kinematic effects that should be considered when interpreting future SZ data for individual clusters. One of the main outcomes of this work is SZpack, a numerical library which allows very fast and precise (<~0.001% at frequencies h nu <~ 20kT_g) computation of the SZ signals up to high electron temperature (kT_e ~ 25 keV) and large peculiar velocity (v/c ~ 0.01). The accuracy is well beyond the current and future precision of SZ observations and practically eliminates uncertainties related to more expensive numerical evaluation of the Boltzmann collision term. Our new approach should therefore be useful for analyzing future high-resolution, multi-frequency SZ observations as well as computing the predicted SZ effect signals from numerical simulations.